📝 SummarXiv

Abstract

The dielectric response of mono-alcohols exhibits a strong Debye peak generally attributed to the dynamics of hydrogen-bonds (HB) supramolecular structures through a mechanism that remains unclear in many aspects. In this letter, we use standard all-atom molecular dynamics simulations to investigate this phenomenon in 1-propanol, a prototypic monoalcohol, over a wide temperature range covering a significant change in dielectric permittivity. We obtained dielectric spectra showing a Debye peak in good agreement with experimental data, which we decomposed into the self and cross parts of the dipolar correlations. The latter extends over a few molecular distances and contributes increasingly to the Debye peak upon cooling. To investigate its physical origin, we analyzed the HB structures by identifying clusters from simulation snapshots. Below 300~K, the dielectric permittivity was shown to arise almost entirely from intra-cluster cross-correlations. Furthermore, by tracking the dipole decorrelation of groups of molecules initially belonging to the same cluster, we found that supramolecular structures play a key role in stabilizing cross-correlation over time scales longer than the relaxation of individual molecules.